Methods, apparatus and data structures for preserving address and service level information in a virtual private network

Abstract

Supporting virtual private networks by using a new layer 3 address to encapsulate a network-bound packet so that its context information, from which a layer 2 (e.g., MAC) address can be derived, is preserved. If this encapsulation was not done, the layer 2 address would change over each segment of the network. Thus, the encapsulation preserves the concept of group identification, using at least a part of the context, over the entire network and not just at the edge of the network. If a packet is received from the network (to be forwarded to a customer), the layer 3 address that was added in the encapsulation is stripped off. The original layer 3 destination address may be used with a client device addressing table to determine a new context information, and a layer 2 (e.g., MAC) address of a destination client device. If the client device addressing table does not include entries corresponding to the layer 3 destination address, an address resolution protocol (or “ARP”) may be broadcast to request such information or contents of inbound packets may be observed (snooping). The packet may then be forwarded to an aggregation device.

Description

§ 1. BACKGROUND OF THE INVENTION§ 1.1 Field of the Invention[0001]The present invention concerns methods, apparatus and data structures for aggregating traffic, which may originate from various media transport types, for presentation to a router, such as an access router of a network. Further, the traffic aggregation performed by the present invention may be done such that customers can be identified and such that customer device addressing information is available. Moreover, the traffic aggregation performed by the present invention may be done such that the service provided to a group of customers may be monitored; multicast groups are secure; and the access router can control access to services, facilitate virtual private networks, and facilitate the provision of different quality of service and / or class of service levels.§ 1.2 Related Art[0002]The description of art in this section is not, and should not be interpreted to be, an admission that such art is prior art to the presen...

AI Technical Summary

Problems solved by technology

For example, a voice over Internet application may require low delays, but may tolerate some packets being dropped, to the extent that such dropped packets cannot be perceived or are not annoying to users.

This is because it would be pointless to retransmit erroneous packets in such a real-time application.

Data transport may tolerate delays but will not tolerate transmission errors.

However, such routers cannot accommodate the physical connections of the tens or hundreds of thousands of individual services that they could otherwise accommodate.

For example, assuming that customers had a very high end 10 or 100 Mbps service (or communications access links capable of such service levels), such routers could process the data flow from 12,800 or 1,280 customers, respectively, but could not accommodate those numbers of physical connections.

Naturally, a larger number of physical connections (e.g., for lower end service(s)) could not be accommodated.

Aside from physically requiring a lot of space, using a DSLAM for this purpose would be expensive on a per port basis.

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